Methods and compositions for repelling ants, wasps and termites with repellents

ABSTRACT

Disclosed are methods and compositions for retarding the movement of ants, wasps, and/or termites to a specific locus by use of farnesol or a farnesol related compound.

This application is a continuation of application Ser. No. 07/939,897,filed Sep. 4, 1992, now abandoned.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention is directed to methods and compositions for retarding themovement of ants, wasps and/or termites to a specific locus by use of arepellent. Specifically, in this invention, ants, wasps and/or termitesare retarded from moving to a specific site by use of farnesol orrelated compounds. In one embodiment, farnesol or a related compound isimpregnated into a compatible matrix and the resulting matrix is used asa repellent barrier to retard the movement of ants, wasps, and/ortermites to a specific locus.

2. References

The following references are cited in this application as superscriptletters at the relevant portion of the application:

A Holldobler, B., et al., "Communication in Social Hymenoptera" in "HowAnimals Communicate", Sebeok, Editor, Indiana University Press,Bloomington, Ind., pp. 418-471 (1977)

B Butenandt, et al., Ueber Einen Duftstoff Aus Der Mandibeldruese derBlattschneiderameise Atta sexdens Rubropilosa, Forel. Arch. Anat.Microscop. Morph. Exp., 48:13-19 (1959)

C Blum, et al., "Alkanes and Terpenes in the Mandibular Glands of Attaspecies", Comp. Biochem. Physiol., 26:291-299 (1968)

D Schildknecht, H., "Chemical Ecology--a Chapter of Modern NaturalProducts Chemistry", Angew. Chem. Int. Ed. Eng., 151:214-222 (1976)

E Lloyd, et al., "Chemistry of Mandibular and Dufour's Gland Secretionsof Ants in Genus Myrmecocystus", J. Chem. Ecol., 15:2589-2599 (1989)

F Honda, "Defensive Potential of Components of the Larval OsmeterialSecretion of Papilionid Caterpillars Against Ants", Physiol. Entomol.,8:173-179 (1983)

G Scheffrahn, et al., "4,11-Epoxy-cis-Eudesmane, Soldier CephalicSecretion of the Nearctic Desert Termite, Amitermes minimus Light(Termitidae: Termitinae), Experienta, 40:1136-1137 (1984)

H Post, et al., "Colony Defense Against Ants by Polistes Fuscatus(Hymenoptera:Vespidae) in Wisconsin", J. Kans. Entomol. Soc., 54:599-615(1981)

I Post, et al., "Identification of Ant Repellent Allomone Produced bySocial Wasp Polistes Fuscatus (Hymenoptera:Vespidae)", J. Chem. Ecol.,10:1799-1807 (1984)

J Henderson, et al., "Response of Aphid-Tending Ants to a RepellentProduced by Wasps (Hymenoptera:Formicidae, Vespidae), Ann. Entomol. Soc.Am., 82:515-519 (1989)

K Kistner, et al., "Alarm Pheromone of Lasius (Dendrolasius) Spathepus(Hymenoptera:Formicidae) and its Possible Mimicry by Two Species ofPella (Coleoptera:Staphylinidae)", Ann. Entomol. Soc. Amer., 64:589-594(1971)

L Huth, et al., "Defense Chemicals from Abdominal Glands of ThirteenRove Beetle Species of the Subtribe Staphylina(Coleoptera:Staphylinidae:Staphylininae)", J. Chem. Ecol., 16:2691-2711(1990)

M Maschwitz, "Gefahrenalarmstoffe and Gefahrenalarmierung Bei SozialenHymenoptera", Z. Vergl. Physiol., 47:569-655 (1964)

N Scheffrahn et al., "Defensive Ecology of Forelius Foetidus and itsChemosystematic Relationship to F. (=Iridomyrmex) pruinosus(Hymenoptera:Formicidae:Dolichoderinae)", Environ. Entomol.,13:1502-1506 (1984)

O Key, et al., "Effects of Gaster Extract Trail Concentration on TrailFollowing Behavior in the Argentine Ant, Iridomyrmex humilis", J. InsectPhysiol., 27:363-370 (1981)

P Das, et al., "Non-Repellency of Two Insect Growth Regulators WithJuvenile Hormone Activity to Blattella Germanica", Entomol. Exp. Appl.,20(2):195-198 (1976)

Q Stirrup-M™ available from Fermone Inc., Glendale, Ariz.

R Corey, et al., J. Am. Chem. Soc., 92:6637 et seq. (1970)

All publications mentioned in this specification are indicative of thelevel of skill of those skilled in the art to which this inventionpertains. All publications are herein incorporated by reference in theirentirety to the same extent as if each individual publication wasspecifically and individually indicated to be incorporated by referencein its entirety.

State of the Art

The art is continuously searching for effective and relatively safemethods for retarding the movement of ants, wasps and termites into aspecific locus such as homes, trees, yards, etc. In general, ants,wasps, and/or termites are typically removed from a specific locus withan insecticide which is toxic to the ants, wasps, and/or termites.However, such use of insecticides is temporary and sometime thereafterthe ants, wasps, and/or termites may reinfest the locus. Additionally,the use of insecticides causes several major concerns. Initially, theuse of insecticides poses environmental concerns and indiscriminate useof such insecticides on cultivated acreage can result in contaminationof agricultural products, possible contamination of ground water, etc.;whereas the indiscriminate use of insecticides in a household settingcan result in contamination of food stuffs with the insecticide as wellas possible exposure of the occupants to high concentrations ofinsecticide. Secondly, insecticides typically do not discriminatebetween ants, wasps, and termites and useful insects which might beexposed to the insecticide. For example, in an orchard setting, the useof such insecticides can result in removal of insects, i.e., bees whichare required to pollinate the blossoms.

One alternative approach to the use of insecticides for controllingcertain insects is the use of attractants or repellents. In this regard,it is well known that many social insects (e.g., ants, wasps, termites,and the like) communicate with others of their species and with theirenvironment largely through behaviorally active chemicals^(A). Some ofthe chemicals cause repellency or inhibition of ongoing behavior andothers cause attraction.

In regard to the above, alarm compounds released from an ant which isinjured or attacked may cause a variety of specific behaviors, includingrepellency, in nearby ants of the same species.

The alarm compounds of some ants have received considerable study. Anexample is the genus Atta in which the mandibular glands contain a richmedley of chemicals including citral^(B), nerol^(C), geraniol^(C),β-pinene^(D), citral^(D), farnesol^(D) and 14 other compounds^(D).

Another example of a chemical medley constituting ant alarm compoundswas identified by Lloyd et al.^(E) who found methyl salicylate to be aprincipal alarm component produced by workers of several species ofhoney ants, Myrmecocystus spp. A number of terpenoids were also found inthese worker ants, including neral, geranial, citronellol, and limoneneand presumably, these also possess alarm activity.

The various species of Formica, when alarmed, spray mixtures of formicacid and Dufour's gland secretion toward the enemy, with the mixturesserving simultaneously as defensive substances and alarm compounds^(M).

The ant, Forelius foetidus, secretes 2-heptanone which, when usedsingly, functions as an alarm compound. It also secretescis,trans-iridodial, which, when mixed with 2-heptanone, elicitsdefensive behavior in Forelius foetidus and repellent behavior in twoother ants, Solenopsis maniosa and Crematogaster californica^(N).

On the other hand, there is apparently no alarm compound released by theworkers of the Argentine ant, Iridomyrmex humilis (Mayr)^(O).

Other insects release repellents against predatory insects includingants. For example, α-pinene is released in the secretion of the larvalosmeteria of papilionid caterpillars to ward off ants^(F) ;4,11-epoxy-cis-eudesmane is released by the Neartic desert termite,Amitermes minimus, to repel the ant Crematogaster californica^(G) ; thetropical social wasps, Polistes fuscatus, secrete methyl palmitate intotheir nest supports to prevent ants of several species from preying ontheir brood^(H),I,J ; when necessary, staphylinid beetles of the genusPella release citronellal to disperse ants of the species Lasiusspathepus in addition to releasing iridoid dialdehyde, α-pinene, neral,geranial, nerol, and citronellol^(K),L.

In insect management, attractants are typically employed in combinationwith a trap which can optionally include an insecticide. In thisembodiment, the insects are induced to move to the trap by theattractant and once there are trapped within and, when an insecticide isused, the insects are killed by the insecticide.

On the other hand, repellents are typically employed in solution (e.g.,an aqueous solution) or are incorporated into a matrix. Whenincorporated into a matrix, the resulting matrix is positioned so as toform a barrier between the insects and a specific site where the insectsare not to enter.

The use of repellents for agricultural and/or household insectmanagement provides several advantages over the use of insecticides.First, because of their natural activity, the repellent is veryefficient in repelling insects from a specific site. Second, the highactivity of the repellent can permit the use of significantly lowerconcentrations of active ingredient as compared to insecticides and, insome cases, less than 20 grams per acre are required to effectrepellency. In turn, when used at less than 20 grams per acre, the EPAregistration guidelines for acceptance of the repellent become morefeasible.

However, notwithstanding the above, one problem heretofore encounteredwith the use of matrices containing a repellent is that over arelatively short period of time, the repellent can lose substantialactivity. The reasons for this rapid loss of repellent activity is notknown with certainty but it is possible that it can relate to highvolatility of the repellent, oxidation of the repellent, etc. orcombinations of these reasons.

In any event, the rapid loss of activity causes several problems.Initially, when activity is rapidly lost, it is not feasible toincorporate the repellent into the matrix at the time of manufacture.Rather, it is necessary to add the repellent to the matrix at or shortlybefore positioning the matrix at the intended site. Secondly, even ifthe repellent is incorporated into the matrix at the time the matrix ispositioned at its intended site, the matrix will need repeatedreplacements in order to effect continued insect repellency from theintended site. In any event, the entire process of impregnating thematrix, positioning the matrix and repeating this process several timesbecomes rather labor intensive.

In view of the above, a matrix impregnated with a repellent havingprolonged repellent activity would represent a significant advance inthe use of repellents in insect management.

This invention is directed to the discovery that farnesol type compoundsare useful in repelling ants, wasps, and termites and is furtherdirected to the discovery that these compounds unexpectedly provide forprolonged activity when incorporated into a matrix.

In regard to the above, it is noted that while farnesol has beendisclosed as a repellent for the German cockroach, Blattellagermanica,^(P) it is also noted that a mixture containing farnesol iscommercially sold as an attractant for mites^(Q). However, there appearsto be no disclosure that farnesol type compounds would be an effectiverepellent for ants, wasps and termites or that, when combined with acompatible matrix, these compounds would provide for prolongedrepellency to ants, wasps, and termites.

SUMMARY OF THE INVENTION

As noted above, this invention is directed, in part, to the discoverythat farnesol and related compounds (e.g., nerolidol) are effectiverepellents to ants, wasps and termites. This invention is furtherdirected, in part, to the discovery that when farnesol, compoundsrelated to farnesol, or mixtures thereof, are incorporated into acompatible matrix, the resulting matrix possesses significantlyprolonged repellent effectiveness.

In view of the above, in one of its method aspects, this invention isdirected to a method for retarding ants, wasps, and/or termites frommoving to a specific locus which comprises applying a repellenteffective amount of a compound of formula I or of formula II: ##STR1##between the ants, wasps, and/or termites and the locus

wherein R, R₁, R₂ and R₃ are independently selected from the groupconsisting of hydrogen and lower alkyl of 1 to 3 carbon atoms,

R₄ is selected from the group consisting of --CH₃, --CH₂ OH, --CH₂ Cl,--CH₂ Br, --CH₂ OC(O)R₆, and --COOR₇ wherein R₆ is hydrogen or alkyl offrom 1 to 4 carbon atoms and R₇ is hydrogen, alkyl of from 1 to 4 carbonatoms; and

R₅ is selected from the group consisting of hydrogen, hydroxyl, chloro,bromo, and --OC(O)R₆ wherein R₆ is hydrogen or alkyl of from 1 to 4carbon atoms.

In another of its method aspects, this invention is directed to a methodfor the prolonged retardation of ant and/or termite movement to aspecific locus which comprises the steps of:

(a) impregnating a compatible matrix with a repellent effective amountof a compound of formula I or of formula II: ##STR2##

wherein R, R₁, R₂ and R₃ are independently selected from the groupconsisting of hydrogen and lower alkyl of 1 to 3 carbon atoms,

R₄ is selected from the group consisting of --CH₃, --CH₂ OH, --CH₂ Cl,--CH₂ Br, --CH₂ OC(O)R₆, and --COOR₇ wherein R₆ is hydrogen or alkyl offrom 1 to 4 carbon atoms and R₇ is hydrogen, alkyl of from 1 to 4 carbonatoms; and

R₅ is selected from the group consisting of hydrogen, hydroxyl, chloro,bromo, and --OC(O)R₆ wherein R₆ is hydrogen or alkyl of from 1 to 4carbon atoms;

(b) positioning the compatible matrix formed in step (a) above betweensaid locus and said ants, wasps, and/or termites; and

(c) retaining said matrix in said position for a period of at least 28days.

In one of its composition aspects, the present invention is directed toa liquid composition comprising:

(a) a compatible matrix;

(b) a repellent effective amount of a compound of formula I or offormula II: ##STR3##

wherein R, R₁, R₂ and R₃ are independently selected from the groupconsisting of hydrogen and lower alkyl of 1 to 3 carbon atoms,

R₄ is selected from the group consisting of --CH₃, --CH₂ OH, --CH₂ Cl,--CH₂ Br, --CH₂ OC(O)R₆, and --COOR₇ wherein R₆ is hydrogen or alkyl offrom 1 to 4 carbon atoms and R₇ is hydrogen, alkyl of from 1 to 4 carbonatoms; and

R₅ is selected from the group consisting of hydrogen, hydroxyl, chloro,bromo, and --OC(O)R₆ wherein R₆ is hydrogen or alkyl of from 1 to 4carbon atoms; and

(c) a compatible solvent.

In another of its composition aspects, the present invention is directedto a composition comprising a compatible matrix containing a repellenteffective amount of a compound of formula II: ##STR4## wherein R, R₁, R₂and R₃ are independently selected from the group consisting of hydrogenand lower alkyl of 1 to 3 carbon atoms, and

R₅ is selected from the group consisting of hydrogen, hydroxyl, chloro,bromo, and --OC(O)R₆ wherein R₆ is hydrogen or alkyl of from 1 to 4carbon atoms and R₇ is hydrogen, alkyl of from 1 to 4 carbon atoms.

In a preferred embodiment, in the compounds of formula I, R, R₁, R₂ andR₃ are methyl and R₄ is --CH₂ OH (i.e., farnesol). In another preferredembodiment, in the compounds of formula II, R, R₁, R₂, and R₃ are methyland R₅ is hydroxyl (i.e., nerolidol).

In still another preferred embodiment, the compounds of formula I andformula II are employed to retard the movement of ants and particularlyArgentine ants, Iridomyrmex humilis.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

This invention is directed to methods and compositions for disruptingthe movement of ants, wasps, and/or termites to a specific locus. Themethods are achieved by the use of farnesol related compounds, i.e., thecompounds of formula I and II. In a preferred embodiment, a compound offormula I or of formula II or a mixture of compounds of formula I and/orformula II are combined into a compatible matrix. However, prior todiscussing this invention in further detail, the following terms willfirst be defined.

Definitions

As used herein, the following terms have the following meanings:

The terms "ant" and "wasp" refers to the ant and wasp members of theorder Hymenoptera and include, by way of example only, the speciesIridomyrmex humilis, Solenopsis xyloni, Formica spp. (ants), Vespavulgaris (wasps) and the like.

The term "termite" refers to the termite members of the order Isopteraand include, by way of example only, the species Reticulitermeshesperus, Zootermopsis augusticollis, Kalotermes minor, and the like.

The term "locus" refers to any site to which movement of ants, wasps,and/or termites is to be retarded. The particular site is not criticaland includes, by way of example, the interior of a home, a particulararea of land, trees (e.g., citrus trees), and the like.

For example, it is well known that ants are a serious pest of a numberof agricultural crops. The deleterious action of the ants can be direct(i.e., leaf cutting ants) or indirect. The indirect deleterious actionof ants occurs, for example, in that certain species tend homopteroushoney-dew-producing insects such as aphids, soft scales, and mealybugs.Through their transporting of these homopterous insects to new growth onthe plants, and through their role in warding off potential parasitesand predators, ants may create situations where the tended insectsassume serious pest status, whereas, in the absence of ants, the insectswould often be regulated through the action of beneficial predatory andparasitic species. One particular agricultural crop where ants are aserious pest are citrus trees where the ants move from the ground up tothe tree to the leaves where they tend homopterous honey-dew-producinginsects. Thus, in this situation, the locus for preventing movement ofthe ants would be the tree itself.

In another example, the locus would be the interior of a house wheremovement of ants, wasps, and/or termites from the outside into thehome's interior is desirably retarded.

In any event, the locus is a variable which is fixed solely by that sitewhere retardation of ant movement is desired.

The term "compatible matrix" refers to any material in which one or moreof the farnesol related compounds of formula I and formula II are eithersoluble or miscible and which materials do not significantly alter ordegrade the repellent activity of these compounds to ants, wasps, and/ortermites over a period of at least 7 days and preferably at least 28days and more preferably at least 60 days.

Suitable compatible matrices are known in the art and include, by way ofexample, polymeric materials such as polyethylenes, polyvinyls includingTygon™, polyisoprene such as rubber, polypropylenes, copolymers ofethylene and propylene; polybutenes such as Stickem Special™ (apolybutene based composition commercially available from SeabrightEnterprises, Emeryville, Calif.), polysaccharides such as cotton twine;Tanglefoot™ (a compatible matrix which is commercially available fromThe Tanglefoot Company, Grand Rapids, Mich.), floor wax, and the like.Combinations of compatible matrices can be employed (i.e., cotton twineand Tanglefoot™). The particular compatible matrix employed with thefarnesol related compound is not critical.

In one preferred embodiment, the compatible matrix is combined with thefarnesol related compound of formula I or formula II into a volatilecompatible solvent. The compatible solvent acts to solubilize thecompatible matrix and the farnesol related compound. Upon application ofthis solution to its intended site, the volatile solvent evaporatesleaving a matrix containing farnesol impregnated thereon. Thisembodiment permits the facile application of a film of matrix containingfarnesol over a desired site.

Compatible solvents are those in which the farnesol related compound andthe compatible matrix are soluble to at least 10 milligrams permilliliter of solvent and which do not significantly degrade theactivity of the farnesol related compound. Volatile compatible solventsare those having a boiling point of 100° C. or less at atmosphericpressure and include, by way of example, acetone, ethanol, methanol,isopropanol, saturated hydrocarbons such as hexane, cyclohexane,aromatic compounds such as xylene, toluene, etc., and the like.

Farnesol Related Compounds

The farnesol related compounds employed herein are preferably thosedepicted by formula I and II above and include farnesol (i.e., informula I, R, R₁, R₂, and R₃ are --CH₃ ; and R₄ =--CH₂ OH), nerolidol(i.e., in formula II, R, R₁, R₂ and R₃ =--CH₃ and R₅ =--OH) andcompounds related thereto including congeners of farnesol and nerolidolas well other geometric isomers. Farnesol and nerolidol are well knowncompounds which can be isolated from natural sources. Farnesol andnerolidol are also commercially available (e.g., Aldrich ChemicalCompany, Milwaukee, Wis.). Moreover, the synthesis of these compounds isknown in the art which includes a synthesis of farnesol disclosed byCorey et al^(R).

Similarly, the other compounds described in formula I and formula IIabove can be readily synthesized by well known techniques. For example,derivatives of farnesol and nerolidol wherein one or more of R, R₁, R₂and R₃ groups are hydrogen or lower alkyl of from 1 to 3 carbon atomsbut where R, R₁, R₂, and R₃ are not all --CH₃ can be readily preparedfollowing art known synthetic procedures by merely substituting theappropriate starting materials in such syntheses.

Likewise, farnesol derivatives wherein R₄ is --CH₂ OC(O)R₆ and nerolidolderivatives where R₅ is --OC(O)R₆ are readily prepared by reactingfarnesol type compounds (i.e., compounds of formula I which terminate ina R₄ group equal to --CH₂ OH) and nerolidol type compounds (i.e.,compounds of formula II which contain an R₅ group equal to --OH) with asuitable carboxylic acid, acid halide, acid anhydride or activated esterunder acylating conditions well known to the skilled artisan. Forexample, reaction of farnesol or nerolidol with acetyl chloride [CH₃C(O)Cl] preferably in the presence of a tertiary amine which scavengesthe acid generated during reaction leads to the corresponding ester(i.e., R₄ is --CH₂ OC(O)CH₃ in farnesol and R₅ is --OC(O)CH₃ innerolidol).

The deoxy derivatives of farnesol (i.e., R₄ =--CH₃) and nerolidol (i.e.,R₅ =H) and the halo derivatives thereof (i.e., R₄ =--CH₂ Cl and --CH₂Br; and R₅ =--Cl and --Br) are also readily accomplished by artrecognized procedures. For example, the preparation of the haloderivatives can be achieved by reaction of farnesol type compounds ornerolidol type compounds with thionyl chloride or thionyl bromide. Thebromo derivative can be reduced to the deoxy derivative by reactionwith, for example, lithium aluminum hydride.

Lastly, the preparation of carboxylic acid and ester derivatives offarnesol type compounds (i.e., R₄ =--CO₂ R₆) is also accomplished by artrecognized procedures starting with farnesol type compounds (i.e., R₄=--CH₂ OH). For example, the primary alcohol can be oxidized under mildconditions, for example, cold chromic acid followed by silver oxideoxidation of the aldehyde to provide for the acid (i.e., R₄ =--CO₂ H)which optionally can then be esterified by art recognized proceduresusing a C₁ to a C₃ alcohol.

Farnesol and nerolidol are preferred compounds for use herein becausethey are produced in nature and are known to be comparably non-toxic.

Methodology

The methodology for using a farnesol related compound of formula I or IIas an ant and/or termite repellent is generally accomplished by placinga repellent effective amount of such a compound or a mixture of suchcompounds between the ants, wasps, and/or termites and the locus whereone desires to retard movement therein of the ants, wasps, and/ortermites.

The method of application is not critical and many well known methodscan be used. For example, appropriate amounts of a farnesol relatedcompound of formula I or II can be dissolved into an appropriatecompatible solvent and dispensed as a solution onto the intended locus.Preferably, the solvent employed is a volatile solvent (i.e., has aboiling point of about 100° C. or less) that will evaporate over aperiod of time. Alternatively, a farnesol related compound can becombined with an appropriate propellant and used as a spray forapplication onto the intended locus.

In another embodiment, a farnesol related compound is impregnated into acompatible matrix and the matrix is then employed as a barrier layerbetween the ants, wasps, and/or termites and the locus from which onedesires to retard ant, wasp, and/or termite movement therein.Impregnation of the farnesol related compound into the compatible matrixcan be achieved by any well known methods known in the art. For example,the farnesol related compound can be dissolved into a compatiblevolatile solvent and the resulting solution added to the matrixwhereupon evaporation of the solvent results in impregnation of thefarnesol related compound into the compatible matrix. In this regard,the matrix can be cotton twine, polymers such as polyvinyls (such asTygon™), polyisoprenes (such as rubber), polyethylene, polypropylene orcopolymers thereof, polybutenes (such as Stickem™), etc., Tanglefoot™,and the like. In another embodiment, a compatible matrix such as TreeTanglefoot™ is thinned by heating and then the farnesol related compoundis added directly thereto. The mixture can then be combined with twineor other compatible matrices. The resulting combination is then appliedaround the selected locus to form a barrier which retards movement ofants, wasps, and/or termites there past.

One example of this mode of application is the incorporation of afarnesol related compound into a floor wax composition such as thosewhich are readily commercially available. Upon application of the floorwax and removal of any volatile solvent, the resulting wax will containfarnesol. Another example of this mode of application is theimpregnation of a farnesol related compound into a compatible matrixsuch as Tygon™, rubber, Stickem™, or Tanglefoot™. The resulting matrixis then banded around the locus from which ants, wasps, and/or termitesare to be retarded (e.g., the trunk of a tree or the wall of a house).

Regardless of the method of application, the amount of the farnesolrelated compound used is a repellent effective amount. That is to saythat sufficient amounts of the farnesol related compound or mixture ofcompounds is used so as to retard the movement of ants, wasps, and/ortermites to the selected locus. In a preferred embodiment, the farnesolrelated compound is applied at a rate of at least about 0.05 milligramsper square foot and more preferably at a rate of about 0.5 milligramsper square foot to about 5 grams per square foot. In another embodiment,the application rate of the farnesol related compound is about 20 gramsper acre or less. When used at this rate, the EPA registration for theuse of this compound is simplified.

When employed to retard movement of ants (e.g., Argentine ants) intotrees, the farnesol related compound of formula I or II is preferablyincorporated into Stickem™ which is then banded around tree trunks.About 0.008 to about 2 grams of a farnesol related compound ispreferably employed per tree trunk having a diameter of from about 3 toabout 5 centimeters.

In another embodiment, ants, wasps, and/or termites are removed from thelocus prior to application of the farnesol related compound. Removal canbe achieved by conventional methods such as by using an insecticide.After removal, the farnesol related compound retards reinfestation ofthe locus by ants, wasps, and/or termites.

In a preferred embodiment, effective retardation of ant, wasp, and/ortermite movement is accomplished when movement into the locus is reducedby at least 50% and preferably by at least 80% and more preferably by atleast 95% as compared to control.

In addition to retarding movement of ants, wasps, and/or termites, thefarnesol related compounds disclosed herein are effective in retardingthe movement of other insects and arachnida such as spiders, fleas,ticks, etc. Accordingly, in another embodiment, a repellent effectiveamount of a farnesol related compound can be formulated into a matrixsuitable for use in retarding flea infestation of pets.

The following examples are offered to illustrate this invention andshould not be construed in any way as limiting its scope.

EXAMPLES General Procedures

The examples set forth below were conducted in a planting of young,non-bearing lemon trees. The trees were about 2 meters high and the stemdiameter ranged from 3 to 5 centimeters at 10 centimeters above the soilsurface. The trees were heavily infested with a variety ofhoney-dew-producing Homoptera, and the Argentine ants made trails fromtheir nests in the ground, up the trunks to the vicinities of theinsects they were tending.

A double layer of duct tape was wrapped around the trunks of the trees,at about 10 centimeters above the soil surface. Candidate chemicalstested for disrupting ant trail following (i.e., retarding ant movement)were placed on specified lengths of cotton twine or Tygon™ or rubbertubing, which were then wrapped two or three times around the treetrunk, over the duct tape. The tape was intended to protect the treetrunk from possible phytotoxic effects of the tested chemicals. Undermost circumstances, the twine or tubing was held in position by staplesdriven through the duct tape and into the tree trunk. An exception tothis procedure occurred in the case of Stickem™ or Tree-Tanglefoot™impregnated cotton twine, the ends of which were tucked under the loopsof twine wrapped around the trunk.

Chemicals tested were obtained from commercial sources and are listed inExamples 1-5 below. When a given chemical was tested in conjunction witha matrix of sticky material such as Stickem Special™ (commerciallyavailable from Seabright Enterprises, Emeryville, Calif.) or TreeTanglefoot™ (commercially available from The Tanglefoot Company, GrandRapids, Mich.), the sticky material was first thinned through heating;the specified amount of sticky material was then mixed with thecandidate chemical; finally, this sticky material-chemical mixture wasplaced in a glass jar containing a specified length of cotton gardentwine (Puritan™ twine) and was continuously agitated until essentiallyall of the mixture was incorporated in and on the twine.

Efficacy of disruption of any trail-following and foraging was evaluatedon specified days following placement of the chemical-impregnated twineor tubing around tree trunks, by counts of the numbers of ants walkingacross the twine or tubing during a 2 minute interval. Ants were countedwithout regard to whether they were proceeding up or down the trunk.Untreated control counts were made of ants crossing over a band ofuntreated twine around control tree trunks.

Example 1

Following the general procedures set forth above, nineteen chemicalswere tested for efficacy through inoculation of 1 gram of each onto 30centimeter lengths of cotton twine, which were then wrapped around thetrunks of test trees. Each tree was regarded as a plot, and treatmentswere replicated three times in a randomized complete blocks design.Counts of ants passing over the test twine were made on the sixth dayfollowing application. The results of this test are set forth in Table Ibelow:

                  TABLE I                                                         ______________________________________                                                         Mean no. 1/2 minutes of ants                                 CHEMICAL         passing barrier on day 6                                     ______________________________________                                        farnesol         0.0 a                                                        methyl eugenol   0.6 ab                                                       β-citronellol                                                                             0.7 abc                                                      bornyl acetate   0.9 abc                                                      eugenol          1.7 bcd                                                      methyl myristate 2.1 cde                                                      citral           4.6 def                                                      methyl salicylate                                                                              4.7 def                                                      safrole          5.4 efg                                                      limonene         5.7 efg                                                      linalool         6.1 fgh                                                      benzaldehyde     8.7 fgh                                                      methyl anthranilate                                                                            10.0 fgh                                                     limonene oxide   10.1 fgh                                                     α-terpineol                                                                              11.5 fgh                                                     myrcene          11.5 fgh                                                     α-pinene   12.5 fgh                                                     β-pinene    13.5 gh                                                      3-carene         16.0 h                                                       Untreated        10.1 fgh                                                     ______________________________________                                         .sup.1 Each treatment chemical was replicated three times in a randomized     complete blocks design. Counts of ants crossing the barriers in 2 minutes     were transformed to ln(X + 1) for ANOVA. Duncan's Multiple Range Test was     performed on transformed means. Means in the same column followed by a        common letter are not significantly (5% probability) different. Means         presented here are transformed back to the original scale.               

The results of Table I indicate that farnesol is an excellent repellent6 days after placement of the barrier around the tree trunk.

Example 2

Following the procedures set forth above, testing was conducted toevaluate the efficacy of methyl eugenol incorporated into 30 centimeterlength of Tygon tubing of three different sizes or into 30 centimeterlength of one size of latex rubber tubing, and of citral incorporatedonly into the rubber tubing. Approximately a 1:1 weight ratio of thesechemicals to matrix were incorporated into the matrix by occasionalagitation over a 24-hour period. The results of this test are set forthin Table II below:

                  TABLE II                                                        ______________________________________                                        passing barrier on day                                                        Chemical    Tubing    2        6      9                                       ______________________________________                                        methyl eugenol                                                                            Tygon.sup.2                                                                             2.4 ab   0.9 ab 2.4 abc                                             Tygon.sup.3                                                                             0.6 a    0.7 ab 1.5 ab                                              Tygon.sup.4                                                                             0.0 a    0.0 a  0.6 a                                               Rubber.sup.5                                                                            0.2 a    0.0 a  1.0 a                                   citral      Rubber.sup.5                                                                            0.3 a    2.7 bc 8.2 bc                                  untreated             4.6 b    7.4 c  18.8 c                                  ______________________________________                                         .sup.1 Each treatment chemical was replicated three times in a randomized     complete blocks design. Counts of ants crossing the barriers in 2 minutes     were transformed to ln(X + 1) for ANOVA. Duncan's Multiple Range Test was     performed on transformed means. Means in the same column followed by a        common letter are not significantly (5% probability) different. Means         presented here are transformed back to the original scale.                    .sup.2 0.8 mm ID × 2.38 mm OD, holds 2.1 g of chemical                  .sup.3 1.59 mm ID × 4.76 mm OD, holds 5.6 g of chemical                 .sup.4 4.76 mm ID × 7.94 mm OD, holds 13.2 g of chemical                .sup.5 6.35 mm ID × 7.94 mm OD, holds 3.0 g of chemical            

The above results evidence that methyl eugenol was more active inretarding the movement of Argentine ants than was citral. However, evenat the heaviest application of methyl eugenol in tygon, at about 13grams per tree, complete deterrence of ant movement was only seen forabout one week.

Example 3

Some of the chemicals employed in Example 1 were mixed as either 10 or40 weight percent solutions in Stickem™, which was then incorporated atthe rate of 2 grams formulated material into 50 cm lengths of cottontwine. The treated lengths of twine were placed around tree trunks andevaluated as described above. The results of this evaluation are setforth in Table III below:

                  TABLE III                                                       ______________________________________                                                        Mean no. 1/2 minutes ants                                              Weight passing barrier on day                                        Chemical   Percent  3        7       14                                       ______________________________________                                        farnesol   10       0.0 a    0.9 ab  9.9 ab                                              40       0.0 a    0.0 a   2.4 a                                    β-Citronellol                                                                       10       5.7 b    9.0 bcd 9.0 ab                                              40       0.0 a    2.7 abc 49.8 b                                   methyl eugenol                                                                           10       9.0 b    16.2 cd 13.3 ab                                             40       0.6 a    4.2 abcd                                                                              7.4 a                                    citral     10       6.1 b    14.3 cd 26.5 ab                                             40       1.6 ab   28.2 d  30.2 ab                                  Stickem ™ alone  3.2 ab   5.5 bcd 12.4 ab                                  untreated           12.5 b   18.8 cd 21.6 ab                                  ______________________________________                                         .sup.1 Each treatment chemical was replicated three times in a randomized     complete blocks design. Counts of ants crossing the barriers in 2 minutes     were transformed to ln(X + 1) for ANOVA. Duncan's Multiple Range Test was     performed on transformed means. Means in the same column followed by a        common letter are not significantly (5% probability) different. Means         presented here are transformed back to the original scale.               

The above results evidence that complete retardation of ant foraging forseven days after application was accomplished with 40 weight percentfarnesol treatment (giving 0.8 g farnesol per tree). By three days afterapplication, and continuing through 14 days, farnesol exhibits the bestprolonged repellency activity of the compounds tested.

Example 4

Farnesol and Stickem™ were tested at higher application rates followingthe general procedure set forth above. In this example, farnesol and a1:1 mixture of farnesol:Stickem™ mixture were prepared as above and thenplaced onto 50-cm lengths of cotton twine, wrapped around tree trunks inthe manner described above. Also tested were 30 centimeter lengths ofrubber tubing, each containing 3 grams of farnesol. The results of thistest are set forth in Table IV below:

                  TABLE IV                                                        ______________________________________                                                 Mean no. 1/2 minutes ants                                            Composition                                                                            passing barrier on day                                               Applied  7       14      27    48    77    122                                ______________________________________                                        A        0.0 a   0.6 a   4.9 a 0.0 a 0.6 a 4.9 a                              B        0.0 a   0.0 a   0.0 a 0.0 a 0.0 a 0.0 a                              C        6.0 b   1.3 a   1.5 a 6.0 b 1.3 a 1.5 a                              D        21.9 b  23.0 b  52.2 b                                                                              21.9 b                                                                              23.0 b                                                                              52.2 b                             ______________________________________                                         .sup.1 Each treatment chemical was replicated three times in a randomized     complete blocks design. Counts of ants crossing the barriers in 2 minutes     were transformed to ln(X + 1) for ANOVA. Duncan's Multiple Range Test was     performed on transformed means. Means in the same column followed by a        common letter are not significantly (5% probability) different. Means         presented here are transformed back to the original scale.               

In this table, the composition (Comp.) applied is as follows:

A=50 cm of twine containing 2 grams of farnesol

B=50 cm of twine containing 2 grams of Stickem™+2 grams of farnesol

C=30 cm of latex rubber tubing (6.35 mm ID×7.94 mm OD) containing 2grams of farnesol

D=Untreated

The results of this test indicate that farnesol alone, at 2 grams pertwine per tree, provided effective (over 90% as compared to control)retardation of movement for about 4 weeks; rubber tubing containing 3grams of farnesol per tree provided effective retardation of movementfor about 7 weeks; and 2 grams of farnesol in 2 grams of Stickem™provided effective retardation for at least 17 weeks.

Example 5

Following the general procedure set forth above, additional chemicalswere tested as mixtures of Stickem™ (2 grams of chemical in 2 grams ofStickem™). These were compared for efficacy with a farnesol/Stickem™mixture. Also tested were a farnesol/Tree Tanglefoot™ mixture, TreeTanglefoot™ alone, and Stickem™ alone. The results of these tests areset forth in Table V below:

                  TABLE V                                                         ______________________________________                                                 Mean no. 1/2 minutes ants                                            Comp.    passing barrier on day                                               Applied  7        14       21     50     95                                   A        1.4 ab   4.3 ab   4.1 ab                                             B        26.0 c   35.6 b   65.3 b                                             C        1.8 ab   8.7 ab   4.8 ab                                             D        1.3 a    14.8 b   11.5 b                                             E        1.4 ab   13.0 b   9.8 b                                              F        0.0 a    0.0 a    0.0 a  0.0 a  0.0 a                                G        0.0 a    0.0 a    0.0 a  0.5 a  35.5 a                               H        17.5 c   11.6 b   22.9 b 52.7 b 48.7 a                               I        1.34 bc  24.5 b   26.1 b 56.5 b 155.8 b                              J        27.3 c   33.8 b   33.8 b 58.3 b 135.6 b                              ______________________________________                                         .sup.1 Each treatment chemical was replicated five times in a randomized      complete blocks design. Counts of ants crossing the barriers in 2 minutes     were transformed to ln(X + 1) for ANOVA. Duncan's Multiple Range Test was     performed on transformed means. Means in the same column followed by a        common letter are not significantly (5% probability) different. Means         presented here are transformed back to the original scale.               

In this table, the composition (Comp.) applied is as follows:

A=Stickem™+3,6-dimethyl-4-octyne-3,6-diol

B=Stickem™+abietic acid

C=Stickem™+nerol

D=Stickem™+linalyl acetate

E=Stickem™+citral dimethyl acetate

F=Stickem™+farnesol

G=Tree Tanglefoot™+farnesol

H=Stickem™ alone

I=Tree Tanglefoot198 alone

J=Untreated

The above results evidence that there is no significant differencebetween Stickem™ and Tree Tanglefoot™ alone in disrupting ant movement.Both materials were penetrated almost immediately (within 7 days) bysignificant numbers of ants. However, farnesol mixed with TreeTanglefoot™ gave effective disruption of ant movement for 7 weeks, andfarnesol mixed with Stickem™ gave effective retardation of ant movementfor about 14 weeks.

Example 6

A laboratory bioassay was conducted to compare the repellency ofnerolidol to farnesol in repelling the Argentine ant. This bioassay wasconducted by measuring the numbers of ants crossing a barrier havingnerolidol or farnesol impregnated into bees wax. Specifically, the beeswax was heated to liquid, the appropriate amount of compound was addedand the solution stirred. The resulting liquid compositions was streakedinto a circle around a food source (sucrose/water) and the number ofants passing the circle per unit time was measured and then compared tothe untreated control (bees wax alone). The difference in the number ofants passing past the control and the test composition divided by thecontrol and multiplied by 100 was used as a measure of percentrepellency. The results are set forth in Table VI below:

                  TABLE VI                                                        ______________________________________                                        Weight %                                                                      of Compound     % Repellency                                                  ______________________________________                                        1.0% Farnesol   no decrease (average of 5 runs)                               3.0% Farnesol    98% (average of 5 runs)                                      0.03% Nerolidol  63% (average of 4 runs)                                      0.10% Nerolidol  73% (average of 4 runs)                                      0.30% Nerolidol  93% (average of 4 runs)                                      1.0% Nerolidol  100% (average of 4 runs)                                      3.0% Nerolidol  100% (average of 4 runs)                                      ______________________________________                                    

The above results evidence that farnesol and nerolidol (a farnesolrelated compound) are both effective in retarding the movement of ants.These results also evidence that nerolidol is significantly more activethan farnesol in retarding the movement of ants. For example, theretardation arising from the use of 0.3 weight percent nerolidol wereapproximately equivalent to those achieved by using 3 weight percentfarnesol.

Other farnesol related compounds could be substituted for eitherfarnesol or nerolidol in the above examples including, by way ofexample, farnesol derivatives such as where R, R₁, R₂ and R₃ are methyland R₄ is --CH₂ OC(O)R₆, --CH₂ Cl, --CH₂ Br, and --CO₂ H; and nerolidolderivatives where R, R₁, R₂ and R₃ are methyl and R₅ is --OC(O)R₆, --Cl,--Br. Similarly, other compatible matrices could be substituted forStickem™, Tree Tanglefoot™, cotton twine, and bees wax in the aboveexamples.

What is claimed is:
 1. A method for retarding ants, wasps, and/ortermites from moving to a specific locus which comprises:a) selecting acompound of formula I or of formula II: ##STR5## ; and b) applying anon-insecticidal composition consisting essentially of a repellenteffective amount of said compound and a compatible matrix between theants, wasps, and/or termites and the locus to thereby prevent the ants,wasps and/or termites from moving to said locus wherein R, R₁, R₂ and R₃are independently selected from the group consisting of hydrogen andlower alkyl of 1 to 3 carbon atoms, R₄ is selected from the groupconsisting of --CH₃, --CH₂ OH, --CH₂ Cl, --CH₂ Br, --CH₂ OC(O)R₆, and--COOR₇ wherein R₆ is hydrogen or alkyl of from 1 to 4 carbon atoms andR₇ is hydrogen, alkyl of from 1 to 4 carbon atoms, R₅ is selected fromthe group consisting of hydrogen, hydroxyl, chloro, bromo, and --OC(O)R₆wherein R₆ is hydrogen or alkyl of from 1 to 4 carbon atoms.
 2. Themethod according to claim 1, wherein a compound of formula I isemployed.
 3. The method according to claim 1, wherein a compound offormula II is employed.
 4. The method according to claim 2, wherein R,R₁, R₂, and R₃ are methyl.
 5. The method according to claim 4, whereinR₄ is --CH₂ OH.
 6. The method according to claim 3, wherein R, R₁, R₂,and R₃ are methyl.
 7. The method according to claim 6, wherein R₅ is--OH.
 8. The method according to claim 1, wherein the movement of antsis retarded.
 9. The method according to claim 8, wherein the ants areArgentine army ants.
 10. The method according to claim 1 wherein thelocus is selected from the group consisting of the interior of a homeand trees.
 11. A method for retarding ants, wasps and/or termites frommoving to a locus which comprises:a) selecting a compound from the groupconsisting of farnesol and nerolidol; b) applying a non-insecticidalcomposition consisting essentially of a repellent effective amount ofsaid compound and a compatible matrix between the ants, wasps, and/ortermites and the locus to thereby prevent the ants, wasps and/ortermites from moving to said locus, wherein said locus is selected fromthe group consisting of the interior of homes and trees.
 12. A methodfor the prolonged retardation of ant, wasp and/or termite movement to aspecific locus which comprises the steps of:(a) impregnating acompatible matrix with a composition consisting essentially of anon-insecticidal repellent effective amount of a compound of formula Ior of formula II: ##STR6## wherein R, R₁, R₂ and R₃ are independentlyselected from the group consisting of hydrogen and lower alkyl of 1 to 3carbon atoms, R₄ is selected from the group consisting of --CH₃, --CH₂OH, --CH₂ Cl, --CH₂ Br, --CH₂ OC(O)R₆, and --COOR₇ wherein R₆ ishydrogen or alkyl of from 1 to 4 carbon atoms and R₇ is hydrogen, alkylof from 1 to 4 carbon atoms; and R₅ is selected from the groupconsisting of hydrogen, hydroxyl, chloro, bromo, and --OC(O)R₆ whereinR₆ is hydrogen or alkyl of from 1 to 4 carbon atoms; (b) positioning thecompatible matrix formed in step (a) above between said locus and saidants, wasps, and/or termites to thereby prevent said ants, wasps and/ortermites from moving to said locus; and (c) retaining said matrix insaid position for a period of at least 28 days.
 13. The method accordingto claim 12, wherein a compound of formula I is employed.
 14. The methodaccording to claim 12, wherein a compound of formula II is employed. 15.The method according to claim 12, wherein R, R₁, R₂, and R₃ are methyl.16. The method according to claim 15, wherein R₄ is --CH₂ OH.
 17. Themethod according to claim 14, wherein R, R₁, R₂, and R₃ are methyl. 18.The method according to claim 17, wherein R₅ is --OH.
 19. The methodaccording to claim 12, wherein the movement of ants is retarded.
 20. Themethod according to claim 19, wherein the ants are Argentine army ants.21. The method according to claim 12 wherein the locus is selected fromthe group consisting of the interior of a home and trees.
 22. A methodfor the prolonged retardation of ant, wasp and/or termite movement to aspecific locus which comprises the steps of:(a) impregnating acompatible matrix with a composition consisting essentially of anon-insecticidal repellent effective amount of a compound selected fromthe group consisting of farnesol and nerolidol; (b) positioning thecompatible matrix formed in step (a) above between said locus and saidants, wasps, and/or termites to thereby prevent said ants, wasps and/ortermites from moving to said locus; and (c) retaining said matrix insaid position for a period of at least 28 days.
 23. The method of claim11 wherein the insects to be retarded are ants.
 24. The method of claim22 wherein the insects to be retarded are ants.